engGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-01730010.22069/ijpp.2013.11081108INFOhttp://ijpp.gau.ac.ir/article_1108_1eea1a7cfd5df28b1e47e5ccfc7a0c2b.pdfengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017335537210.22069/ijpp.2013.11091109Nitrogen effects on yield, quality and K/Na selectivity of sugar beets grown on clays under semi-arid, irrigated conditionsJ.T. Tsialtastsialtas01@windowslive.com1N. Maslaris2Aristotle University of Thessaloniki, Faculty of Agriculture, Laboratory of Agronomy, 541 24 Thessaloniki, Hellas.Hellenic Sugar Industry SA, Agronomic Research Service, 574 00 Sindos, Hellas.In a four-year experiment, five nitrogen rates (0, 60, 120, 180 and 240 kg N ha-1)
were tested over irrigated sugar beets grown on clays, underMediterranean
conditions, in centralGreece. There, sugar beets are commonly grown under water
shortages, high temperatures and high soil Na concentrations. Contrary to previous
reports, N rates did not affect significantly population density (as assessed by root
number at harvest) and sucrose content in fresh and dry root weight (SC and SCD,
respectively). Yield response to N was year dependent and only in one out of four
seasons, was there a positive effect of N on sugar yield and white sugar yield. In
that case, the estimated optimum N dose was high (220 kg N ha-1). Increasing N
rates increased significantly N assimilation (as assessed by petiole NO3-N and root
α-amino N) and water content in root (WCR) but decreased biomass partitioning to
root (lower harvest index). Selective absorption (SA, the preferential uptake of K
over Na in roots) decreased with increasing N rates and it was negatively correlated
with sugar beet N nutrition indices (petiole NO3-N and root α-amino N). A
negative correlation between SA and petiole NO3-N was also evident when data
combined over years, indicating that strong Na exclusion was associated with poor
N nutrition, a contradiction to previous reports. The higher the SA, the lower the
WCR indicating less dilution of sucrose in root and thus, the higher the SC.
Moreover, high SA evoked sucrose accumulation in roots as it was shown by its
positive correlation with SCD.http://ijpp.gau.ac.ir/article_1109_8a268f93a04287c0693021dce7b6af9b.pdfBeta VulgarisFertilizationRoot qualitySalinitySodiumengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017337439210.22069/ijpp.2013.11101110Corn yield response to polymer and non-coated urea placement and timingsP.R. Nash1K.A. Nelson2P.P. Motavalli3Dept. of Soil, Environmental and Atmospheric Sciences, Univ. of Missouri, Columbia, MO 65211.Div. of Plant Sciences, Univ. of Missouri, Novelty, MO 63460.Dept. of Soil, Environmental and Atmospheric Sciences, Univ. of Missouri, Columbia, MO 65211.Poorly drained claypan soils can increase the importance of tillage and N
management for corn (Zea mays L.) production. Field research in 2008, 2009 and
2010 (high rainfall years) near Novelty, MO (40° 1' N, 92° 11' W) sought to
determine the effect of polymer-coated urea (PCU) placement [strip-tillage (ST) deep
banded and no-till (NT) broadcast] and application timing (fall, early preplant and
preplant) on red clover (Trifolium pratense L.) biomass and corn response compared
to non-coated urea (NCU) and anhydrous ammonia (AA) in the presence and
absence of nitrapyrin a nitrification inhibitor. Strip-tillage reduced clover dry weights
20% in 2008 and 2009 and early preplant ST reduced dry weights 40 to 45% in 2010
compared to NT. Corn plant population was 8,100 to 8,400 plants ha-1 greater with
ST compared to NT. Preplant applications of AA plus nitrapyrin, AA, ST placement
of PCU and NCU increased grain yields 1 to 1.2 Mg ha-1 compared to fall
applications of these fertilizer sources. Fall and preplant ST placement of PCU
increased grain yields 1.2 Mg ha-1 compared to NCU. Strip-till placement of PCU
and NCU increased yields 2.1 to 3.2 Mg ha-1 over broadcast applications of these
fertilizer sources. Strip-till placement of PCU synergistically increased yield over
NCU and broadcast applications of PCU or NCU due to increased stands and
possibly due to better plant utilization of the banded N fertilizer utility.http://ijpp.gau.ac.ir/article_1110_be1aa12b0bcb01550d7c2099bcdceb00.pdfControlled-release fertilizerCover cropEnhanced efficiency fertilizerNo-tillStrip-tillageengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017339341610.22069/ijpp.2013.11111111Photoperiod and growing degree days effect on dry matter partitioning in Jerusalem artichokeR. Ruttanaprasert1S. Jogloy2N. Vorasoot3T. Kesmala4R.S. Kanwar5C.C. Holbrook6A. Patanothaiaran@kku.ac.th7Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Muang, Khon Kaen, Thailand.Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Muang, Khon Kaen, Thailand.Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Muang, Khon Kaen, Thailand.Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Muang, Khon Kaen, Thailand.Department of Agricultural &Biosystems Engineering Iowa State University, Ames, Iowa, USA.USDA-ARS, Coastal Plain Experiment Station, P.O. Box 748, Tifton, 31793, Georgia, USA.Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Muang, Khon Kaen, Thailand.The effect of photoperiod and growing degree days (GDD) on dry matter and
dry matter partitioning in Jerusalem artichoke was investigated during 2008-09 and
2009-10. Three Jerusalem artichoke genotypes (CN-52867, JA-89 and HEL-65)
were planted in 15 day-intervals between with thirteen different dates (September
20 to March 20) atKhon Kaen University,Thailand. Jerusalem artichoke genotypes
responded differently to varying planting dates for harvest index, shoot dry weight,
leaf area, number of tubers and tuber size. Two genotypes, CN-52867 and JA-89,
were significantly more productive on the planting date of 20 September and they
also performed well on planting dates of 5 October to 20 March. Plant grown in
long photoperiod with a higher number of GDD produced shoot dry weight rather
than greater number of harvestable tubers, while short photoperiod induced high
partitioning of assimilates to harvestable tubers. Jerusalem artichoke plants grown
during short photoperiod were smaller and produced larger tubers than those grown
during long photoperiod. Tuber yield was relatively unchanged across planting
dates. SinceJerusalemartichoke during short photoperiod had smaller plants,
growing Jerusalem artichoke at higher plant population with optimum density is
highly recommended to increase tuber yield. The information obtained in this study
is extremely important for Jerusalem artichoke production and breeding in the
tropical agro-climatic conditions such asThailand.http://ijpp.gau.ac.ir/article_1111_bc3a33d012f9532c354580e436ec6f0e.pdfplanting dateHarvest indexShoot dry weightHelianthus tuberosus LengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017341743610.22069/ijpp.2013.11121112Effect of deficit irrigation on crop growth, yield and quality of onion in subsurface drip irrigationN. Patel1T.B.S. Rajput2Senior Scientist Water Technology Centre, Indian Agricultural Research Institute, New Delhi.Principal Scientist, Water Technology Centre, Indian Agricultural Research Institute, New Delhi.Indiahas the largest area under onion (Allium cepa) crop but its average productivity (14.21 t ha-1) is considerably lower than the world’s average of 19.4 t ha-1. Besides low productivity, irrigation efficiencies are also very low i.e. 30-35% in India. Managing onion crop with less than adequate irrigation water availability is a challenge in several parts of the country. Options of i) deficit irrigation (DI) i.e. 20% or 40% less water application at one of the growth stages of the crop and ii) controlled deficit of 20% or 40% on all growth stages i.e. regulated deficit irrigation (RDI) were explored for maximizing IWUE of onion under deficit water application through subsurface drip irrigation. A field experiment was conducted on onion (var. Agrifound light red) for three years from October to May in 2007-08, 2008-09 and 2009-10 to study the effect of DI and RDI on onion yield and its quality under subsurface drip irrigation. In DI treatments, the crop was provided the irrigation with 60% and 80% of ETc creating water stress of 40 and 20%, respectively at developmental (2nd), bulb formation (3rd) and bulb maturity (4th) crop growth stages. In case of RDI treatments, 20% and 40% water stress was created throughout the crop season by applying the irrigation water at 80% and 60% ETc. The maximum yield (44.7 t ha-1) was obtained in the full-irrigation treatment (T1). In RDI, 20 and 40% deficit water application saved 19.2 and 41.7% water and resulted in 20 and 32% reduction in yield, respectively. In DI, 20% water deficit in the growth stages of 2nd, 3rd and 4th saved 2.1, 13.2 and 4.6% of water with 19.8, 18.3 and 11.2% reduction in yield, respectively in comparison to full irrigation water application. This suggests that RDI is better option of water saving than DI. Saving of water through RDI may be used to irrigate additional cropped area. Strategy suggested for productions of onion crop can be adopted in large scale to offset high cost of onion, which is cause of concern for all stake holders.http://ijpp.gau.ac.ir/article_1112_19cae44d3366cc2b620db01416fc75a4.pdfe drip irrigationOnion yieldwater use efficiencyOnion qualityengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017343745410.22069/ijpp.2013.11131113Assessment of agro-physiological traits for salt tolerance in drought-tolerant wheat genotypesM. Sharbatkharimahish336@yahoo.com1S. Galeshi2Z.S. Shobbar3B. Nakhoda4M. Shahbazi5Department of Crop Production, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran. bDepartment of Molecular Physiology, Agricultural Biotechnology Research Institute of Iran (ABRII), Karaj, 31535-1897, Iran.Department of Crop Production, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran.Department of Molecular Physiology, Agricultural Biotechnology Research Institute of Iran (ABRII), Karaj, 31535-1897, Iran.Department of Molecular Physiology, Agricultural Biotechnology Research Institute of Iran (ABRII), Karaj, 31535-1897, Iran.Department of Molecular Physiology, Agricultural Biotechnology Research Institute of Iran (ABRII), Karaj, 31535-1897, Iran.Salt stress is one of the major constraints for wheat cultivation inIranand leads to
a considerable loss in crop yield each year. In high salinity soils, the reduced osmotic
potential of soil solutes may cause physiological drought. In this study the salt
tolerance of different drought-tolerant bread wheat genotypes were studied by
examining various agronomic and physiological traits, including Na+ and K+
concentrations, the Na+/K+ ratio in leaf and spike, shoot dry weight, leaf greenness,
stomatal conductance, leaf area, osmotic potential, relative water content (RWC) and
grain yield. Two pot experiments were conducted using a completely randomized
design with three replications. Wheat genotypes were grown in pots and irrigated
either with tap water (EC=0.5 dSm-1) or saline water (EC≈18 dsm-1) as control and
salt stress treatments, respectively. Significant differences were observed in all
measured traits between control and stress treatments except for the spike potassium
concentration. Differences between genotypes were significant for all traits except
for RWC and osmotic potential. Among the different genotypes, one drought-tolerant
genotype appeared salt tolerant, three were semi-salt-tolerant, one drought-sensitive
genotype appeared semi-salt-sensitive, and two drought-tolerant genotypes appeared
salt-sensitive and semi-salt-sensitive. This study shows that drought tolerance does
not necessarily lead to salt tolerance. Some physiological traits including Na+
content, leaf area, SPAD number, stomatal conductance and shoot dry weight, which
are significantly correlated with grain yield and show remarkable variations among
wheat genotypes, may be useful parameters for measuring the responses of other
wheat genotypes to high-salinity soils in the field.http://ijpp.gau.ac.ir/article_1113_aee9d3bf5b0d53031f949babc0e0a1b4.pdfSalt stressWheatNa+ contentPhysiological CharacteristicsengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017345547210.22069/ijpp.2013.11141114Land surface modification and crop diversification for enhancing productivity of a VertisolK.G. Mandal1K.M. Hati2A.K. Misra3K.K. Bandyopadhyay4A.K. Tripathi5Directorate of Water Management (ICAR), Bhubaneswar-751 023, India.Division of Soil Physics, Indian Institute of Soil Science (ICAR), Bhopal-462 038, India.Division of Soil Physics, Indian Institute of Soil Science (ICAR), Bhopal-462 038, India.Division of Agricultural Physics, IARI (ICAR), New Delhi-110 012, India.Division of Soil Physics, Indian Institute of Soil Science (ICAR), Bhopal-462 038, India.Vertisols occur extensively in centralIndiaand have high production potentials.
Because of the high clay content (40-60% or more), high bulk density (1.5-1.8
Mg m-3) and related properties, these soils have high moisture storage capacity.
Conversely, these soils become very hard when dry and very sticky when wet.
Since last two decades, scientists, farmers and also the policy makers have been
striving to manage these soils through harnessing the beneficial attributes as well as
overcoming the production constraints. Some of the potential options are efficient
surface land configuration and crop diversification. Field experiments were
conducted at the Research Farm atBhopalto evaluate the land surface
configuration and crop diversification. Results of our experiment on vertisols
showed a considerable reduction in run off of water and also soil loss from broadbed
and furrow (BBF) compared to flat-on-grade (FOG) during rainy season and at
the same time crop productivity was significantly improved in BBF. It enhanced
yield of soybean (Glycine max (L.) Merr.), maize (Zea mays L.), pigeonpea
(Cajanus cajan (L.) Millsp.) as sole and as well as intercropping and sole chickpea
(Cicer arietinum L.) by about 12.7-20.0% over FOG. The yield of crops (soybean,
maize and pigeonpea), expressed as soybean equivalent yield, was compared and it
showed an improvement in yield from different intercropping systems on BBF. The
residual effect of rainy season crops on succeeding chickpea was not significant;
however, its yield in two irrigation (one pre-sowing plus one post-sowing) was
significantly greater than pre-sowing irrigation only in both land configurations.
Water use efficiency (WUE) of chickpea was more under BBF than FOG. The
study elucidates the constraints and potentials of vertisol for crop production
especially with reference to centralIndiaand effective ways to improve crop
productivity through land surface modification and crop diversification.http://ijpp.gau.ac.ir/article_1114_f275ecc4f56af699b45a91ab995fb3ef.pdfVertisolsCrop productionBroad-bed and furrowSoybean-based systemengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017343750410.22069/ijpp.2013.11151115Developing a dynamic yield and growth model for saffron under different irrigation regimesA.R. Sepaskhahsepas@shirazu.ac.ir1M. Amini-Nejad2A.A. Kamgar-Haghighi3Irrigation Department, Shiraz University, Shiraz, I.R. of Iran.Irrigation Department, Shiraz University, Shiraz, I.R. of Iran.Irrigation Department, Shiraz University, Shiraz, I.R. of Iran.Better irrigation management and more efficient management of crop production
require modeling of plant growth and crop yield. More applicable models are usually
simple and requires less and accessible inputs. The objective of this study was to
develop a model for growth and yield prediction of saffron under various irrigation
regimes. In this modeling soil water budget and other simple relationships for
evapotranspiration partitioning, leaf area index determination and leaf dry mattertranspiration
function, corm-transpiration function and saffron-corm function were
used. The developed model was calibrated based on available data of basin irrigation
experiment under different irrigation regimes and verified based on independent data
under different climatic conditions. In calibration, the comparison between predicted
and measured values of different crop parameters did not show any significant
difference (P=0.05) and model was able to estimate LAI (with NRMSE=0.16),
crop evapotranspiration (NRMSE=0.19), surface evaporation (NRMSE=0.22), leaf
dry matter (NRMSE=0.33) and corm yield (NRMSE=0.19) and saffron yield
(NRMSE=0.16) properly. In validation, the statistical results of comparison between
predicted and measured values of various crop parameters were different and model
was able to estimate corm and saffron yield with acceptable accuracy. Furthermore,
this model might be used only for saffron crop because the incorporated crop
functions are developed for saffron.http://ijpp.gau.ac.ir/article_1115_25db0fc35922f724de5f649855da7cc9.pdfSaffron modelingSaffron yieldtotal dry matterEvapotranspirationLeaf area indexCorm yieldengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017350551610.22069/ijpp.2013.11161116Application of the MoDrY model for the estimation of potato yieldingA. Żyromski1W. Szulczewski2M. Biniak-Pieróg3R. Żmud4Wroclaw University of Environmental and Life Sciences, Institute of Environmental Protection and Development.Wroclaw University of Environmental and Life Sciences, Department of Mathematics.Wroclaw University of Environmental and Life Sciences, Institute of Environmental Protection and Development.Wroclaw University of Environmental and Life Sciences, Institute of Environmental Protection and Development.The study was conducted with the application of the model MoDrY (Model-Dry
periods-Yield) for the estimation of the level of potato yields on the basis of dry
periods occurring during the particular periods between the phenological phases of
the crop plant. A characteristic feature of this model, unlike most existing weatheryield
models, is that the principle of its operation is based only on information on
the occurrence of precipitation. In the study the authors used research material from
the years 1971-1983 and 1985-1996 (25 years) and diurnal sums of atmospheric
precipitation from the same periods. Five interphase periods were adopted for the
analyses: planting-emergence, emergence-lateral shoots, lateral shoots-start of
blooming, start of blooming-haulm drying, haulm drying-harvest. The authors also
used a model of changes in the resources of water available for plants during dry
periods. Six measures were adopted to characterise the error of approximation:
coefficient of correlation, coefficient of determination, mean relative error,
RRMSE, EF and CRM. The coefficient of correlation obtained was at the level of
0.92 and the mean relative error at the level of 9.27%. Validation was performed
by means of the Cross Validation test (CV), version LOO.http://ijpp.gau.ac.ir/article_1116_ea027c4374a6dffd4946aff3c0475f6d.pdfpotatoDry periodsPhenological phasesWeather-yield modelMoDrYengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017351753610.22069/ijpp.2013.11171117Maize productivity and nutrient use efficiency in Western Kenya as affected by soil type and crop managementA.F. Ngome1M. Becker2M.K. Mtei3F. Mussgnug4Institute of Crop Science and Resource Conservation (INRES), Department of Plant Nutrition, University of Bonn, Karlrobert Kreiten Straße 13, 53115 Bonn, Germany.Institute of Crop Science and Resource Conservation (INRES), Department of Plant Nutrition, University of Bonn, Karlrobert Kreiten Straße 13, 53115 Bonn, Germany.Institute of Crop Science and Resource Conservation (INRES), Department of Plant Nutrition, University of Bonn, Karlrobert Kreiten Straße 13, 53115 Bonn, Germany.Africa Rice Center (AfricaRice), 01 BP 2031, Cotonou, Benin.Low soil fertility and high weed infestation are the main culprits for the declining
maize production inWestern Kenya. Technology packages to address these
constraints exist, but their effectiveness is likely to be influenced by variability in soil
types and farm management practices in the region. Trials were conducted during the
2008/2009 cropping seasons to investigate the nutrient use efficiency and yield
response of maize to some recommended management options for smallholder
farmers on three dominant soil types ofWestern Kenyanamely Acrisol, Nitisol and
Ferralsol. Irrespective of seasons, average maize yields were highest on Nitisol (3.6
t ha-1) and lowest on Ferralsol (2.1 t ha-1). Maize yield gaps (difference between
potentially achievable and actual yields) differed by season and soils with 4-5 t ha-1
on Nitisol and about 6 t grain ha-1 on Acrisol and Ferralsol. On Nitisol, the largest
share of this yield gap (80%) was closed by the addition of mineral fertilizer, while
on Ferralsol, reduced tillage could close 25-60% of the yield gap. The highest
agronomic (13-39 kg grain kg-1 N) and physiological (50-160%) N use efficiencies
were obtained with mineral fertilizers, while the addition of organic amendments
resulted in the highest P use efficiency (15-154 kg grain kg-1 P), irrespective of soil
type and season. As soil types and management options differentially affect yields
and nutrient use efficiency of maize, there is a need for field-specific targeting of
technologies to address maize production constraints inWestern Kenya.http://ijpp.gau.ac.ir/article_1117_20e50d345f99ecb6c136cfa2f64eb8aa.pdfAcrisolFerralsolNitisolNutrient uptakeYield GapengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017353756810.22069/ijpp.2013.11181118Determination of plant traits that affect genotype × location (G×L) interaction in peanut using the CSM-CROPGRO-Peanut modelC. Putto1A. Patanothaiaran@kku.ac.th2S. Jogloy3K.J. Boote4G. Hoogenboom5Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand.Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand.Department of Plant Science and Agricultural Resources, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand.Department of Agronomy, University of Florida, Gainesville, Florida 32611-0500, USA.AgWeatherNet, Washington State University, Prosser, WA 99350-8694, USA.Genotype × environment (G×E) interaction complicates the identification of
superior genotypes. An understanding its causes is needed for a more effective
breeding strategy. The objective of this study was to determine the plant traits that
cause genotype × location (G×L) interaction for pod yield in peanut using a modeling
approach. The CSM-CROPGRO-Peanut model was used to simulate pod yield for
17 peanut genotypes for 14 locations representative of all peanut production areas in
Thailandusing 30 years of historical weather data. Sensitivity analysis was used to
determine the effects of individual and combinations of plant traits on pod yield and
yield response to environments by varying the value of one or more cultivar
coefficients and then evaluating their effects. The results showed that the cultivar
coefficients that showed major effects were the duration from first seed to
physiological maturity (SDPM), maximum leaf photosynthesis rate (LFMAX), the
maximum fraction of daily growth that is partitioned to seed and shell (XFRT),
single seed filling duration (SFDUR) and the duration of pod addition (PODUR).
Those having minor effects were the duration from emergence to first flower
(EMFL), maximum leaf size (SIZLF) and maximum seed weight (WTPSD). The
cultivar coefficients that caused the differences in both mean yield and yield response
to locations between peanut genotypes in different pairs included LFMAX, XFRT,
SDPM, SFDUR and PODUR, but the causal characters differed among pairs of
genotypes. It was concluded that changing the degree of genotypic response to
environments is possible through selection for a combination of some of these traits,
and that model simulation could be used to identify those traits.http://ijpp.gau.ac.ir/article_1118_194c0b2c8f4af2267e37e2cb11b4e542.pdfG×E interactionCultivar adaptationYield stabilityCrop modelSensitivity analysisengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017356959610.22069/ijpp.2013.11191119Growth and physiologic response of rapeseed (Brassica napus L.) to deficit irrigation, water salinity
and planting methodA. Shabani1A.R. Sepaskhahsepas@shirazu.ac.ir2A.A. Kamgar-Haghighi3Irrigation Department, Shiraz University, Shiraz, I.R. of Iran.Irrigation Department, Shiraz University, Shiraz, I.R. of Iran.Irrigation Department, Shiraz University, Shiraz, I.R. of Iran.Salinity and water stress reduces the ability of plant to take up water and decrease
growth rate, photosynthesis rate (An) and stomatal conductance (gs) of plants. In this
study, effects of deficit irrigation with different salinity levels and planting method
(in-furrow and on-ridge) as strategies for coping with water and salinity stress on
physiologic properties of rapeseed was investigated in a two years experiment.
Irrigation treatments consisted of full irrigation (FI) and 0.75FI and 0.50FI in first
year and 0.65FI and 0.35FI in second year and salinity treatments of irrigation water
were 0.6 (well water), 4.0, 7.0 m and 10.0 dS-1 in first year and 0.6, 4.0, 8.0 and 12.0
dSm-1 in second year. Planting in-furrow increased seasonal dry matter by 8.4 and
9.6%, respectively at first and second year (with frost occurrence in dormant period
in second year) relative to on-ridge planting. In-furrow planting increased maximum
leaf area index compared with on-ridge planting by 12.8% for second year. Deficit
irrigation and salinity decreased dry matter, leaf area index and had no significant
effect on crop growth rate (CGR) and relative growth rate (RGR). Decrease in
applied water resulted in lower stomatal conductance (gs) and photosynthesis rate
(An) and salinity had no significant effect on these traits. Ratio of photosynthesis rate
to transpiration rate (leaf scale transpiration efficiency, An/T) decreased when leaf
vapor pressure deficit (VPD) increased and in water and salinity stress conditions,
transpiration efficiency of rapeseed decreased. A linear function between An/T and
VPD with negative slope indicated that in higher VPD, An/T decreased, therefore in
water stress condition or in arid and semi-arid region in comparison with humid
region An/T of rapeseed decreased. There was no significant difference between the
effects of water salinity levels (up to 12 dS m-1) and planting method on slopes of the
relationships between An and gs and VPD. As forage plant, rapeseed can be
cultivated in soils with salinity of 3.4 dS m-1 and 11.7% deficit irrigation can be
imposed without dry matter reduction and in-furrow planting method was proposed
in salinity and water stress conditions in comparison with on-ridge planting.http://ijpp.gau.ac.ir/article_1119_d2891a3e57eab9094c80885a64f7919d.pdfPhysiologic propertiesPlanting methodRapeseedSalinityWater stressengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017359761410.22069/ijpp.2013.11201120Seed yield and some physiological traits of safflower as affected by water deficit stressH. Amini1A. Arzani2F. Bahrami3Department of Agronomy and Plant Breeding, College of Agriculture, Isfahan University of Technology, Isfahan 8415683111, Iran.Department of Agronomy and Plant Breeding, College of Agriculture, Isfahan University of Technology, Isfahan 8415683111, Iran.Department of Agronomy and Plant Breeding, College of Agriculture, Isfahan University of Technology, Isfahan 8415683111, Iran.Safflower (Carthamustinctorius L.) is an oilseed crop adapted to drought prone
arid and semi-arid environments. This study was conducted to evaluate the effects
of water deficit stress on antioxidant activity, membrane stability index (MSI), leaf
chlorophyll content, leaf area index (LAI) and their relationship with seed yield
using 64 safflower genotypes grown under normal and water deficit stress field
condition. Plants were grown under normal irrigation until branching growth stage
when water deficit stress was applied to the plants. Analysis of variance showed
the significant effects of genotype, water deficit and their interactions on the
physiological traits that examined. Water deficit stress significantly decreased leaf
area index, leaf chlorophyll content and the membrane stability index means over
all 64 genotypes whereas it caused significant increase in antioxidant compounds
(APX and POX). The results also revealed the positive and significant correlations
between antioxidant enzyme activities with seed yield under water deficit
conditions. The stress susceptibility index (SSI) identified water-deficit tolerant
genotypes (Kordestan 3 and C411) that did have outstanding yield performance per
se in stress environments.http://ijpp.gau.ac.ir/article_1120_527da699a82f1467f022a7b87138c6f1.pdfAntioxidantSusceptibility indexDroughtengGorgan University of Agricultural SciencesInternational Journal of Plant Production1735-68141735-80432013-04-017361563610.22069/ijpp.2013.11211121Evaluation of growth, yield, relative performance and heat susceptibility of eight wheat (Triticum aestivum L.) genotypes grown under heat stressAkbar Hossaintanjimar2003@yahoo.com1M.A.Z. Sarker2M. Saifuzzaman3J.A. Teixeira da Silva4M.V. Lozovskaya5M.M. Akhter6Wheat Research Center, Bangladesh Agricultural Research Institute, Dinajpur-5200 Bangladesh.Faculty of Biological Sciences, Astrakhan State University, Astrakhan 414056, Russia.aWheat Research Center, Bangladesh Agricultural Research Institute, Dinajpur-5200 Bangladesh.Wheat Research Center, Bangladesh Agricultural Research Institute, Dinajpur-5200 Bangladesh.Faculty of Agriculture and Graduate School of Agriculture, Kagawa University, Ikenobe, Miki-cho, 761-0795, P.O. Box 7, Miki cho post office, Ikenobe 3011-2, Kagawa-Ken, 761-0799, Japan.Faculty of Biological Sciences, Astrakhan State University, Astrakhan 414056, Russia.Wheat Research Center, Bangladesh Agricultural Research Institute, Dinajpur-5200 Bangladesh.Eight spring wheat cultivars were evaluated under three heat stress conditions
(early, late and very late) in order to identify suitable cultivars to develop heattolerant
genotypes resistant to future global warming. Results from the study indicate
that stress did not negatively affect flag leaf area in ‘Prodip’ and ‘Sufi’, flag leaf dry
matter partitioning in ‘Prodip’, ‘BARI Gom-26’ and ‘Shatabdi’, above-ground dry
matter partitioning in ‘Shatabdi’ and ‘BARI Gom-26’, seedling emergence in ‘Sufi’
and ‘BARI Gom-26’, or tiller production in ‘Sufi’ and ‘BARI Gom-26’. With respect
to lower yield reduction, relative performance and heat susceptibility index (HSI),
‘Sufi’ was highly heat stress-tolerant, followed by ‘BARI Gom-26’ and ‘Shatabdi’.
On the basis of HSI values in early heat stress and extremely late heat stress
(corresponding to early and extremely late sowing), ‘BARI Gom-26’ (HSI=0.10,
0.65) and ‘Shatabdi’ (0.22, 0.62) were highly tolerant to early heat stress and
moderately tolerant to extremely late heat stress while ‘Sufi’ was highly tolerant
(0.35) to extremely late heat stress and moderately tolerant (0.51) to early heat stress.
All other genotypes were susceptible to heat stress, among which ‘Gourab’ (2.19,
1.46) was the most susceptible followed by ‘Sourav’ (1.19, 1.42), ‘Prodip’ (1.03,
1.23), ‘BARIGom-25’ (1.61, 0.89) and ‘Bijoy’ (1.04, 1.28). Thus, ‘BARIGom-26’,
‘Shatabdi’ and ‘Sufi’ have the greatest potential to be used as high-yielding wheat
genotypes under warm to hot environments and could be used in a breeding
programme to develop heat-tolerant wheat.http://ijpp.gau.ac.ir/article_1121_473a2481e1babb454f403aa4979faefd.pdfHigh-temperatureWheatGenotypeGrowth and development